Finite-difference fluid dynamics computer mathematical models for the design and interpretation of experiments for space flight
Abstract
Numerical methods are used to design a spherical baroclinic flow model experiment of the large scale atmosphere flow for Spacelab. The dielectric simulation of radial gravity is only dominant in a low gravity environment. Computer codes are developed to study the processes at work in crystal growing systems which are also candidates for space flight. Crystalline materials rarely achieve their potential properties because of imperfections and component concentration variations. Thermosolutal convection in the liquid melt can be the cause of these imperfections. Such convection is suppressed in a low gravity environment. Two and three dimensional finite difference codes are being used for this work. Nonuniform meshes and implicit iterative methods are used. The iterative method for steady solutions is based on time stepping but has the options of different time steps for velocity and temperature and of a time step varying smoothly with position according to specified powers of the mesh spacings. This allows for more rapid convergence. The code being developed for the crystal growth studies allows for growth of the crystal as the solid-liquid interface. The moving interface is followed using finite differences; shape variations are permitted. For convenience in applying finite differences in the solid and liquid, a time dependent coordinate transformation is used to make this interface a coordinate surface.
- Publication:
-
NASA STI/Recon Technical Report N
- Pub Date:
- May 1984
- Bibcode:
- 1984STIN...8423852R
- Keywords:
-
- Experiment Design;
- Finite Difference Theory;
- Fluid Dynamics;
- Mathematical Models;
- Spaceborne Experiments;
- Spacelab Payloads;
- Baroclinic Instability;
- Coordinate Transformations;
- Crystal Growth;
- Iteration;
- Liquid-Solid Interfaces;
- Microgravity Applications;
- Space Commercialization;
- Space Processing;
- Fluid Mechanics and Heat Transfer